CEST-based detection of labile protons by ultrafast 2D NMR

IF 2.624
Ricardo P. Martinho , Gregory L. Olsen , Lucio Frydman
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引用次数: 1

Abstract

Chemical exchange saturation transfer (CEST) NMR is widely used for enhancing the sensitivity of low-abundance exchanging sites in general, and for the water-based detection of labile metabolite protons under in vivo conditions in particular. CEST, however, faces a number of limitations when targeting multiple metabolites, including a radiofrequency (RF)-induced broadening of the detected peaks, and relatively long acquisition times deriving from its continuous-wave nature. Methods have been proposed to overcome these limitations, including a Fourier-encoded version of CEST –the Frequency-Labeled EXchange (FLEX) experiment– and the incorporation of background gradients during the RF saturation time. This work explores an alternative avenue, based on spatiotemporally encoded ultrafast (UF) 2D NMR. UF NMR can compress the time-domain indirect-dimension encoding of 2D NMR into a single shot; to exploit these potential time savings, an UF version of the FLEX experiment was taken as starting point, and the multiple t1-incremented amplitude modulation cycles that the FLEX experiment normally requires were replaced by a single-shot spatiotemporal encoding. The ensuing UF 2D FLEX experiment was then used to monitor the spectral signatures of multiple moieties as they exchange with the solvent, by imprinting these onto the water resonance as in the original experiment –but now all within a single shot. Upon incorporating two-scan phase cycling and quadrature detection, the resulting method showed an experimental performance similar to t1-encoded FLEX, while providing significant time savings plus imaging information that could be of further use in in vivo studies. The main advantages, features and drawbacks observed for UF 2D FLEX are briefly discussed.

Abstract Image

基于cest的超快二维核磁共振检测不稳定质子
化学交换饱和转移(CEST)核磁共振通常被广泛用于提高低丰度交换位点的敏感性,特别是在体内条件下对不稳定代谢物质子的水基检测。然而,CEST在针对多种代谢物时面临许多限制,包括射频(RF)诱导的检测峰展宽,以及由于其连续波性质而导致的相对较长的采集时间。已经提出了克服这些限制的方法,包括CEST的傅立叶编码版本-频率标记交换(FLEX)实验-以及在RF饱和时间内结合背景梯度。这项工作探索了一种基于时空编码超快(UF)二维核磁共振的替代途径。UF核磁共振可以将二维核磁共振的时域间接维数编码压缩成一个单镜头;为了利用这些潜在的时间节省,我们以UF版本的FLEX实验为起点,将FLEX实验通常需要的多个t1增量调幅周期替换为单次时空编码。随后的UF 2D FLEX实验被用来监测多个部分与溶剂交换时的光谱特征,方法是像最初的实验一样,将这些特征印在水共振上——但现在所有这些都在一次拍摄中。结合两次扫描相位循环和正交检测,所得到的方法显示出类似于t1编码FLEX的实验性能,同时提供显著的时间节省和成像信息,可以在体内研究中进一步使用。简要讨论了UF 2D FLEX的主要优点、特点和缺点。
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CiteScore
1.90
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